Image display and organic light-emitting display including image shift unit

ABSTRACT

An image display is disclosed. In one embodiment, the display includes a first display panel comprising i) a first image display portion configured to display a first image and ii) a light transmissive portion formed outside the first image display portion and configured to display a second image. The display further includes i) a second display panel spaced apart from the first display panel and configured to generate the second image and ii) an image shift unit configured to shift the generated second image toward the light transmissive portion of the first display panel so that the shifted second image is projected through the light transmissive portion.

CROSS-REFERENCE TO RELATED PATENT APPLICATION

This application claims the benefit of Korean Patent Application No.10-2010-0057114, filed on Jun. 16, 2010, in the Korean IntellectualProperty Office, the disclosure of which is incorporated herein in itsentirety by reference.

BACKGROUND

1. Field

The described technology generally relates to an image display and anorganic-light emitting display including an image shift unit.

2. Description of the Related Technology

An image display such as an organic light-emitting display generallyincludes a dead space (i.e., a non-emissive portion) around an emissiveportion on which an image is displayed. In order to minimize the size ofthe image display and to maximize the size of a display portion, thedead space needs to be minimized.

SUMMARY

One inventive aspect is an image display and an organic-light emittingdisplay wherein a dead space (i.e., a non-emissive portion) is removedso that image quality is improved.

Another aspect is an image display which includes a first display panelincluding a first image display portion for displaying a first image,and a second image display portion that is disposed outside of the firstimage display portion and displays a second image; a second displaypanel that is vertically spaced apart from the first display panel anddisplays the second image; and an image shift unit for shifting thesecond image displayed on the second display panel to the second imagedisplay portion of the first display panel.

The first image display portion may include a first image light-emittingportion for emitting the first image, and the second display panel mayinclude a second image emitting portion for emitting the second image.

The second image display portion may be disposed on a non-emissiveportion of the first display panel.

The second image display portion may be transparent as long as thesecond image is not shifted from the second display panel.

The image shift unit may shift the second image displayed on the seconddisplay panel to the second image display portion according to a one toone correspondence.

The image shift unit may be disposed between the first display panel andthe second display panel.

The image shift unit may include a first reflective surface forreflecting the second image emitted from the second display panel; and asecond reflective surface that is disposed parallel to the firstreflective surface, and reflects the second image reflected on the firstreflective surface to the second image display portion.

The first reflective surface and the second reflective surface may berespectively disposed on surfaces of a prim.

The second display panel may be disposed between the first display paneland the image shift unit.

The image shift unit may include a first reflective surface forreflecting the second image emitted from the second display pane; and asecond reflective surface that is disposed to be symmetrical with thefirst reflective surface, and reflects the second image reflected on thefirst reflective surface to the second image display portion.

The first reflective surface and the second reflective surface may berespectively disposed on a first reflective mirror and a secondreflective mirror that are spaced apart from each other.

The second image display portion may be disposed so as to directlycontact an outside area of the first image display portion.

The second image displayed on the second image display portion may beconsecutively displayed together with an image displayed on the firstimage display portion.

The first display panel may be a flat display.

Another aspect is an organic light-emitting display including a firstorganic light-emitting display panel including: a first image displayportion that is disposed on a substrate, includes a first organiclight-emitting portion, and displays a first image emitted from thefirst organic light-emitting portion; a second image displaying portionthat is disposed outside of the first image displaying portion anddisplays a second image; and a sealing member of a thin film that isstacked on the first image displaying portion and the second imagedisplaying portion; a second organic light-emitting display panel thatis vertically spaced apart from the first display panel, and includes asecond organic light-emitting portion for emitting the second image; andan image shift unit for shifting the second image emitted from thesecond organic light-emitting portion to the second image displayingportion of the first organic light-emitting display panel.

The sealing member may be configured by alternately stacking an organiclayer and an inorganic layer.

The sealing member may be transparent.

The first organic light-emitting display panel may include a first imagedriver for applying an image signal to the first organic light-emittingportion.

The second organic light-emitting display panel may include a secondimage driver for applying an image signal to the second organiclight-emitting portion.

The image shift unit may shift the second image displayed on the secondorganic light-emitting display panel to the second image display portionaccording to one-to-one correspondence.

The image shift unit may be disposed between the first organiclight-emitting display panel and the second organic light-emittingdisplay panel.

The second organic light-emitting display panel may be disposed betweenthe first organic light-emitting display panel and the image shift unit.

Another aspect is an image display comprising: a first display panelcomprising i) a first image display portion configured to display afirst image and ii) a light transmissive portion formed outside thefirst image display portion and configured to display a second image; asecond display panel spaced apart from the first display panel andconfigured to generate the second image; and an image shift unitconfigured to shift the generated second image toward the lighttransmissive portion of the first display panel so that the shiftedsecond image is projected through the light transmissive portion.

In the above display, the first image display portion comprises a firstimage light-emitting portion configured to emit the first image, andwherein the second display panel comprises a second image emittingportion configured to emit the second image.

In the above display, the light transmissive portion is formed on anon-emissive portion of the first display panel. In the above display,the first image display portion includes a self-emissive light emittinglayer, and wherein the light transmissive portion does not include aself-emissive light emitting layer.

In the above display, the image shift unit is further configured toshift the generated second image toward the light transmissive portionaccording to a one to one image correspondence. In the above display,the image shift unit is formed between the first display panel and thesecond display panel. In the above display, the image shift unitcomprises: a first reflective portion configured to first reflect thegenerated second image; and a second reflective portion formedsubstantially parallel to the first reflective portion, and configuredto reflect the first reflected second image toward the lighttransmissive portion.

In the above display, the first and second reflective portions arerespectively formed on opposing surfaces of a prism. In the abovedisplay, the second display panel is formed between the first displaypanel and the image shift unit. In the above display, the image shiftunit comprises: a first reflective portion configured to first reflectthe generated second image; and a second reflective portion formed to besubstantially symmetrical with the first reflective portion, andconfigured to reflect the first reflected second image toward the lighttransmissive portion.

In the above display, the first and second reflective portions arerespectively formed on a first reflective mirror and a second reflectivemirror that are spaced apart from each other. In the above display, thelight transmissive portion abuts the first image display portion. In theabove display, the light transmissive portion is configured to transmitthe second image substantially consecutively to the first imagedisplayed on the first image display portion. In the above display, thesecond display panel is substantially vertically arranged with respectto the first display panel.

Another aspect is an organic light-emitting display comprising: a firstorganic light-emitting display panel comprising: i) a first imagedisplay portion disposed on a substrate and configured to display afirst image emitted from a first organic light-emitting portion, ii) alight transmissive portion substantially surrounding the first imagedisplay portion and configured to display a second image and iii) asealing member formed on the first image display portion and the lighttransmissive portion; a second organic light-emitting display panel thatis spaced apart from the first display panel, and comprises a secondorganic light-emitting portion configured to emit the second image; andan image transfer unit configured to transfer the emitted second imagetoward the light transmissive portion of the first organiclight-emitting display panel so that the transferred second image isprojected through the light transmissive portion.

In the above display, the sealing member comprises at least one organiclayer and at least one inorganic layer which are alternately formed. Inthe above display, the sealing member is transparent. In the abovedisplay, the first image display portion of the first organiclight-emitting display panel comprises a first image driver configuredto apply an image signal to the first organic light-emitting portion,wherein the light transmissive portion of the first organiclight-emitting display panel does not comprise an image driver, andwherein the second organic light-emitting display panel comprises asecond image driver configured to apply an image signal to the secondorganic light-emitting portion.

In the above display, the second organic light-emitting display panel issubstantially vertically arranged with respect to the first organiclight-emitting display panel. In the above display, the image transferunit is further configured to transfer the emitted second image towardthe light transmissive portion according to one-to-one imagecorrespondence. In the above display, the image transfer unit is formedbetween the first organic light-emitting display panel and the secondorganic light-emitting display panel. In the above display, the secondorganic light-emitting display panel is formed between the first organiclight-emitting display panel and the image transfer unit. Another aspectis an organic light-emitting display comprising: a first organiclight-emitting display panel comprising: i) a self-emissive region andii) a non-self-emissive region; a second organic light-emitting displaypanel spaced apart from the first display panel and configured to emitan image; and an image transfer unit configured to transfer the emittedimage toward the non-light emitting region of the first organiclight-emitting display panel so that the transferred image is projectedthrough the non-self-emissive region.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a cross-sectional view of an image display according to anembodiment.

FIG. 2 is a plan view showing a first image and a second image displayedon a first display panel of the image display of FIG. 1, according to anembodiment.

FIG. 3 is a cross-sectional view of an image display according toanother embodiment.

FIG. 4 is a cross-sectional view of an image display according toanother embodiment.

FIG. 5 is an enlarged cross-sectional view of a portion ‘V’ of FIG. 4.

DETAILED DESCRIPTION

Embodiments will now be described more fully with reference to theaccompanying drawings.

FIG. 1 is a cross-sectional view of an image display 1 according to anembodiment.

Referring to FIG. 1, the image display 1 includes a first display panel110, a second display panel 120, and an image shift unit (or imagetransfer unit) 130 disposed between the first display panel 110 and thesecond display panel 120.

The first display panel 110 includes a first image display portion D11displaying a first image I1, and a second image display portion D12 (ora light transmissive portion) disposed outside of or substantiallysurrounding the first image display portion D11 and displaying a secondimage I2.

In one embodiment, as shown in FIG. 1, the second image display portionD12 is disposed on four edge portions of the first image display portionD11. The second image display portion D12 may be disposed on at leastone edge portion of the first image display portion D11.

Although not illustrated in FIG. 1 in detail, the first image displayportion D11 includes a first image emitting portion (not shown) foremitting the first image I1. For example, the first image emittingportion may include a plurality of light-emitting diodes including anorganic self-emissive light-emitting material. Various colors may berealized by a combination of, for example, red, green and bluelight-emitting diodes. Of course, the first image display portion D11may further include a driver (not shown) for driving the first imageemitting portion.

On the other hand, the second image display portion D12 may be disposedoutside of the first image display portion D11 so as to directly contactthe first image display portion D11. In one embodiment, the second imagedisplay portion D12 does not include a separate image emitting portion,and thus does not include a driver for driving the light emittingportion.

Thus, while the second image I2 emitted from a second image displayportion D22 of the second display panel 120 is not shifted ortransferred to the first display panel 110, which will be describedlater, the second image display portion D12 of the first display panel110 is maintained as a dead space, that is, a non-emissive portion, ofthe first display panel 110.

In one embodiment, the second image display portion D12 of the firstdisplay panel 110 displays the second image I2 emitted from the seconddisplay panel 120 without any change in brightness and color. Thus,generally, the more transparent the second image display portion D12,the better the image display 1 is. In this embodiment, since the secondimage display portion D12 does not include a separate image emittingportion and driver, the second image display portion D12 may bemaintained transparent as long as the second image I2 is not displayedon the second image display portion D12.

In one embodiment, as shown in FIG. 2, the second display panel 120 issubstantially vertically spaced apart from the first display panel 110,and is disposed inside of the image display 1. In another embodiment,the second display panel 120 is not vertically spaced apart from thefirst display panel 110, while the image shift unit 130 shifts ortransfers the emitted second image I2 to the second image displayportion D12 of the first display panel 110, such that the second imageI2 is displayed through the second image display portion D12 Thisapplies to the other disclosed embodiments.

The second display panel 120 includes the second image display portionD22 for displaying the second image I2.

Although not illustrated in FIG. 1, the second image display portion D22of the second display panel 120 includes a second image emitting portion(not shown) for emitting the second image I2. For example, the secondimage emitting portion may include a plurality of light-emitting diodes,like the first image emitting portion. Of course, the second imagedisplay portion D22 may include a driver (not shown) for driving thesecond image emitting portion.

The image shift unit 130 is disposed between the first display panel 110and the second display panel 120. The image shift unit 130 shifts ortransfers the second image I2 displayed on the second display panel 120to the second image display portion D12 of the first display panel 110according to a one-to-one correspondence.

The image shift unit 130 includes a first reflective surface 131 thatreflects the second image I2 emitted from the second image emittingportion (not shown) of the second display panel 120, and a secondreflective surface 132 that is disposed substantially parallel to thefirst reflective surface 131, and reflects the second image I2 reflectedon the first reflective surface 131 to the second image display portionD12 of the first display panel 110.

For example, the first reflective surface 131 and the second reflectivesurface 132 may be respectively disposed on surfaces of a substantiallytriangular prism. According to the present embodiment, the firstreflective surface 131 and the second reflective surface 132 may berespectively disposed on surfaces of a single prism 133 having asubstantially parallelogram shape. Alternatively, the first reflectivesurface 131 and the second reflective surface 132 may be respectivelydisposed on surfaces of a reflective mirror (not shown) instead of aprism.

According to the present embodiment, the first reflective surface 131and the second reflective surface 132 are inclined at an inclinationangle of about 45 degrees with respect to display surfaces of the firstdisplay panel 110 and the second display panel 120, but the presentembodiment is not limited thereto. That is, by controlling theinclination angle of the first reflective surface 131 and the secondreflective surface 132, a distance between the first display panel 110and the second display panel 120 may be controlled.

FIG. 2 is a plan view showing the first image I1 and the second image I2displayed on the first display panel 110 of the image display 1 of FIG.1, according to an embodiment.

In the image display 1, the first image I1 emitted from the first imageemitting portion (not shown) of the first display panel 110 is displayedon the first image display portion D11. The second image I2 emitted fromthe second image emitting portion (not shown) of the second displaypanel 120, which is substantially vertically spaced apart from the firstdisplay panel 110, is shifted by the image shift unit 130 disposedbetween the first display panel 110 and the second display panel 120,and then is displayed on the second image display portion D12 of thefirst display panel 110. Thus, the second image I2 is displayed on thesecond image display portion D12 of the first display panel 110, whichis a dead space (i.e., a non-emissive portion), thereby removing thedead space.

The second image I2 is displayed as a boundary image of the first imageI1, which is consecutively displayed on the first image I1.

In some image displays, since the resolution of an image file does notcorrespond to the resolution of an image display, the entire image ofthe image file may not be displayed, and the image may appear to havebeen cropped. In this case, the cropped image is displayed as the secondimage I2 on the second display panel 120, and then is shifted to thesecond image display portion D12 of the first display panel 110 by theimage shift unit 130 so as to be displayed as a boundary image that isconsecutively displayed on the first image I1. Thus, the entire imagemay be displayed without cropping, and may be displayed on a large-sizedscreen without any the dead place.

Hereinafter, an image display 2 according to another embodiment will bedescribed with reference to FIG. 3. The image display 2 will bedescribed in terms of differences from the image display 1 of FIG. 1,and like reference numerals may denote like elements in differentdrawings.

Referring to FIG. 3, the image display 2 includes a first display panel210, a second display panel 220, and an image shift unit 230 disposed onrear surfaces of the first display panel 210 and the second displaypanel 220.

The first display panel 210 includes the first image display portion D11for displaying the first image I1, and the second image display portionD12 that is disposed outside of the first image display portion D11 anddisplays the second image I2.

The second display panel 220 is substantially vertically spaced apartfrom the first display panel 210, and is disposed inside the imagedisplay 1. The second display panel 220 includes the second imagedisplay portion D22 for displaying the second image I2.

Like in FIGS. 1 and 2, the first image display portion D11 of the firstdisplay panel 210 includes a first image emitting portion (not shown)for emitting the first image I1, but the second image display portionD12 of the first display panel 210 does not include a separate imageemitting portion. Thus, while the second image I2 emitted from thesecond image display portion D22 of the second display panel 220 is notshifted to the first display panel 210, the second image display portionD12 of the first display panel 210 is maintained as a dead space, i.e.,a non-emissive portion, of the first display panel 210. However, sincethe second image display portion D12 does not include separate imageemitting portion and driver, the second image display portion D12 may bemaintained to be transparent while the second image I2 is not displayedon the second image display portion D12.

The image shift unit 230 is disposed on rear surfaces of the firstdisplay panel 210 and the second display panel 220. In FIG. 1, thesecond display panel 120 is disposed so that a display surface of thesecond display panel 120, on which the second image I2 is displayed, mayface the first display panel 110. On the other hand, in FIG. 3, thesecond display panel 220 is disposed so that a display surface of thesecond display panel 220 on which the second image I2 is displayed mayface an opposite side of the first display panel 210.

Thus, since the image shift unit 230 is disposed on the rear surface ofthe second display panel 220, the image shift unit 230 may shift thesecond image I2 emitted from the second display panel 220 to the secondimage display portion D12 of the first display panel 210 according to aone to one correspondence by reflecting the second image I2.

The image shift unit 230 includes a first reflective surface 231 forreflecting the second image I2 emitted from the second image emittingportion (not shown) of the second display panel 220, and a secondreflective surface 232 that is disposed to be substantially symmetricwith the first reflective surface 231, and reflects the second image I2reflected on the first reflective surface 231 to the second imagedisplay portion D12 of the first display panel 210.

The first reflective surface 231 and the second reflective surface 232may be respectively disposed on surfaces of a substantially triangularprism, or alternatively, may be respectively disposed on surfaces of areflective mirror (not shown) without a prism.

Hereinafter, an image display 3 according to another embodiment will bedescribed with reference to FIGS. 4 and 5. The image display 3 will bedescribed in terms of differences from the image displays 1 and 2, andlike reference numerals may denote like elements in different drawings.

FIG. 4 is a cross-sectional view of an image display 3 according toanother embodiment. FIG. 5 is an enlarged cross-sectional view of aportion ‘V’ of FIG. 4.

Referring to FIGS. 4 and 5, the image display 3 includes a first displaypanel 310, a second display panel 320, and an image shift unit 330disposed between the first display panel 210 and the second displaypanel 220.

The first display panel 310 includes the first image display portion D11that is disposed on a substrate 311 and displays the first image I1, thesecond image display portion D12 that is disposed outside the firstimage display portion D11 and displays the second image I2, and asealing member 319 including a plurality of thin films that are stackedon the first image display portion D11 and the second image displayportion D12.

Since the second image I2 emitted from the second display panel 320 isshifted to the second image display portion D12 of the first displaypanel 310 through the substrate 311, the substrate 311 may be formed ofa transparent material.

The first image I1 is emitted from a first organic light-emittingportion 316 of the first display panel 310.

The first organic light-emitting portion 316 includes an organiclight-emitting layer 313 interposed between a first electrode 312 and asecond electrode 314. When the first electrode 312 and the secondelectrode 314 function as an anode or a cathode by applying a voltage tothe first electrode 312 and the second electrode 314, electrons andholes injected from the first electrode 312 and the second electrode 314are combined with the organic light-emitting layer 313 to form excitons,and the organic light-emitting layer 313 emits light by the excitons torealize the first image I1. Thus, the image display 3 may have highresolution, high image quality, low power consumption, and longlifetime.

Since the image display 3 is a top emission type that displays an imagetowards the sealing member 319, the first electrode 312 may function asa reflective electrode, and the second electrode 314 may function as atransparent electrode.

The first electrode 312 may include a reflective layer formed of oneselected from the group consisting of Ag, Mg, Al, Pt, Pd, Au, Ni, Nd,Ir, Cr and combinations thereof, and a transparent layer formed of ITO,IZO, ZnO or In₂O₃. The second electrode 314 may be formed of atransparent conductive material such as ITO, IZO, ZnO, or In₂O₃.

The organic light-emitting layer 313 may be formed of a low molecularweight organic material or a high molecular weight organic material.When a low molecular weight organic film is included, the organiclight-emitting layer 313 may have a single or multi-layer structureincluding at least one selected from the group consisting of a holeinjection layer (HIL) (not shown), a hole transport layer (HTL) (notshown), an electron transport layer (ETL) (not shown), and an electroninjection layer (EIL) (not shown). Examples of available organicmaterials may include copper phthalocyanine (CuPc),N,N′-di(naphthalene-1-yl)-N,N′-diphenyl-benzidine (NPB),tris-8-hydroxyquinoline aluminum (Alq3), and the like.

When a high-molecular weight organic layer is included, the organiclight-emitting layer 313 may further include a HTL that is disposed in adirection from the organic light-emitting layer 313 towards an anode. Inthis case, the HTL may be formed of poly(ethylenedioxythiophene)(PEDOT), and the EML may be formed of polyphenylenevinylenes (PPVs) orpolyfluorenes.

The image display 3 including the first organic light-emitting portion316 may be classified into a passive matrix (PM) type and an activematrix (AM) type. In FIGS. 4 and 5, an example of an AM type imagedisplay is illustrated. Although not illustrated in FIGS. 4 and 5 indetail, the image display 3 may include at least one thin filmtransistor (TFT) disposed below the first electrode 321 of each pixel. ATFT electrically connected to the first electrode 321 is a driving TFT,and applies a signal of the first image I1 to each pixel.

A pixel definition layer 315 defines each pixel of the AM type imagedisplay 3. Each pixel includes a combination of red, green and bluelight-emitting layers so as to realize various colors.

The first image display portion D11 of the first display panel 310includes the first organic light-emitting portion 316 emitting the firstimage I1. On the other hand, the second image display portion D12 of thefirst display panel 310 does not include a separate organiclight-emitting portion. Thus, while the second image I2 emitted from thesecond display panel 320 is not shifted to the first display panel 310,the second image display portion D12 of the first display panel 310 ismaintained as a dead space, i.e., a non-emissive portion, of the firstdisplay panel 310.

The sealing member 319 including a plurality of thin films is stacked onthe first image display portion D11 and the second image display portionD12 of the first display panel 310.

Since the organic light-emitting layer 313 constituting the firstorganic light-emitting portion 316 of the image display 3 is generallyvulnerable to moisture or oxygen, the sealing member 319 is used inorder to prevent external moisture and oxygen from penetrating into theorganic light-emitting layer 313.

If a sealing substrate formed of transparent glass is used as thesealing member 319, a sealant (not shown) for sealing a space betweenthe sealing substrate and the substrate 311 needs to be formed betweenthe substrate 311 and the sealing substrate. In this case, due to thesealing substrate and the sealant formed on a dead space, i.e., anon-emissive portion, of the image display 3, it is difficult to displaythe second image I2.

However, the image display 3 includes the sealing member 319 thatcompletely covers the first image display portion D11 and the secondimage display portion D12 of the substrate 311, instead of a sealingsubstrate including a separate sealant as a sealing member.

In FIGS. 4 and 5, the sealing member 319 is configured by stacking asingle inorganic layer 317 and a single organic layer 318, but thepresent embodiment is not limited thereto. That is, the inorganic layer317 and the organic layer 318 may be alternately stacked several times,or a plurality of inorganic layers or a plurality of organic layers maybe stacked.

Since the sealing member 319 is transparent, and is stacked on thesubstrate 311 without any sealant, the second image I2 emitted from thesecond display panel 320 may be displayed.

The second display panel 320 is substantially vertically spaced apartfrom the first display panel 310, and is disposed inside the imagedisplay 3.

The second display panel 320 includes the second image display portionD22 disposed on a substrate 321 and displaying the second image I2, anda sealing member 329 including a plurality of thin films and disposed onthe second image display portion D22.

The second image I2 is emitted from a second organic light-emittingportion 326 of the second display panel 320.

The second organic light-emitting portion 326 includes an organiclight-emitting layer interposed between a first electrode and a secondelectrode, like the first organic light-emitting portion 316.

The image shift unit 330 is disposed between the first display panel 310and the second display panel 320. The image shift unit 330 shifts thesecond image I2 displayed on the second display panel 320 to the secondimage display portion D12 of the first display panel 310 according to aone to one correspondence.

The image shift unit 330 includes a first reflective surface 331 forreflecting the second image I2 emitted from the second organiclight-emitting portion 326 of the second display panel 320, and a secondreflective surface 332 that is disposed substantially parallel to thefirst reflective surface 331, and reflects the second image I2 reflectedon the first reflective surface 331 to the second image display portionD12 of the first display panel 310, like in the image shift unit 130 ofthe image display 1.

In FIGS. 4 and 5, the image display 3 is an organic light-emittingdisplay in which the image shift unit 330 is interposed between thefirst display panel 310 and the second display panel 320, but thepresent embodiment is not limited thereto. That is, the image shift unit330 may be disposed on rear surfaces of the first display panel 310 andthe second display panel 320, like in the image display 2. In oneembodiment, a display surface of the second display panel 320 on whichthe second image I2 is displayed faces an opposite side of the firstdisplay panel 310. In this embodiment, since the image shift unit 330 isdisposed on a rear surface of the second display panel 320, the imageshift unit 330 may shift the second image I2 emitted from the seconddisplay panel 320 to the second image display portion D12 of the firstdisplay panel 310 according to a one to one correspondence by reflectingthe second image I2.

Since the image display 3 includes the sealing member 319 formed bystacking transparent thin films, instead of a sealing substrate that iscompletely adhered to the first image display portion D11 and the secondimage display portion D12 of the first display panel 310 by using asealant, the second image I2 emitted from the second display panel 320is displayed on the second image display portion D12 of the firstdisplay panel 310. Thus, the second image I2 is displayed on the secondimage display portion D12 of the first display panel 310, which is adead space, i.e., as a non-emissive portion, thereby substantiallyremoving the dead space.

According to at leas one of the disclosed embodiments, a second imageemitted from a second display panel is displayed on a second imagedisplay portion of a first display panel, which is a dead space, i.e., anon-emissive portion, thereby substantially removing the dead space.

While the disclosed embodiments have been particularly shown anddescribed with reference to the accompanying drawings, it will beunderstood by those of ordinary skill in the art that various changes inform and details may be made therein without departing from the scope ofthe following claims.

What is claimed is:
 1. An image display comprising: a first displaypanel comprising i) a first image display portion configured to displaya first image and ii) a light transmissive portion formed outside thefirst image display portion and configured to display a second image; asecond display panel spaced apart from the first display panel andconfigured to generate the second image; and an image shift unitconfigured to shift the generated second image toward the lighttransmissive portion of the first display panel so that the shiftedsecond image is projected through the light transmissive portion,wherein the image shift unit comprises: a first reflective portionconfigured to first reflect the generated second image; and a secondreflective portion formed substantially parallel to the first reflectiveportion, and configured to reflect the first reflected generated secondimage toward the light transmissive portion, where the first and secondreflective portions are respectively formed on opposing surfaces of aprism.
 2. The image display of claim 1, wherein the first image displayportion comprises a first image light-emitting portion configured toemit the first image, and wherein the second display panel comprises asecond image emitting portion configured to emit the second image. 3.The image display of claim 1, wherein the light transmissive portion isformed on a non-emissive portion of the first display panel.
 4. Theimage display of claim 1, wherein the first image display portionincludes a self-emissive light emitting layer, and wherein the lighttransmissive portion does not include a self-emissive light emittinglayer.
 5. The image display of claim 1, wherein the image shift unit isfurther configured to shift the generated second image toward the lighttransmissive portion according to a one to one image correspondence. 6.The image display of claim 1, wherein the image shift unit is formedbetween the first display panel and the second display panel.
 7. Theimage display of claim 1, wherein the second display panel is formedbetween the first display panel and the image shift unit.
 8. The imagedisplay of claim 7, wherein the image shift unit comprises: a firstreflective portion configured to first reflect the generated secondimage; and a second reflective portion formed to be substantiallysymmetrical with the first reflective portion, and configured to reflectthe first reflected second image toward the light transmissive portion.9. The image display of claim 8, wherein the first and second reflectiveportions are respectively formed on a first reflective mirror and asecond reflective mirror that are spaced apart from each other.
 10. Theimage display of claim 1, wherein the light transmissive portion abutsthe first image display portion.
 11. The image display of claim 1,wherein the light transmissive portion is configured to transmit thesecond image substantially consecutively to the first image displayed onthe first image display portion.
 12. The image display of claim 1,wherein the second display panel is substantially vertically arrangedwith respect to the first display panel.
 13. An organic light-emittingdisplay comprising: a first organic light-emitting display panelcomprising: i) a first image display portion disposed on a substrate andconfigured to display a first image emitted from a first organiclight-emitting portion, ii) a light transmissive portion substantiallysurrounding the first image display portion and configured to display asecond image and iii) a sealing member formed on the first image displayportion and the light transmissive portion; a second organiclight-emitting display panel that is spaced apart from the first displaypanel, and comprises a second organic light-emitting portion configuredto emit the second image; and an image transfer unit configured totransfer the emitted second image toward the light transmissive portionof the first organic light-emitting display panel so that thetransferred second image is projected through the light transmissiveportion, wherein the image transfer unit comprises: a first reflectiveportion configured to first reflect the emitted second image; and asecond reflective portion formed substantially parallel to the firstreflective portion, and configured to reflect the first reflectedemitted second image toward the light transmissive portion, where thefirst and second reflective portions are respectively formed on opposingsurfaces of a prism.
 14. The organic light-emitting display of claim 13,wherein the sealing member comprises at least one organic layer and atleast one inorganic layer which are alternately formed.
 15. The organiclight-emitting display of claim 13, wherein the sealing member istransparent.
 16. The organic light-emitting display of claim 13, whereinthe first image display portion of the first organic light-emittingdisplay panel comprises a first image driver configured to apply animage signal to the first organic light-emitting portion, wherein thelight transmissive portion of the first organic light-emitting displaypanel does not comprise an image driver, and wherein the second organiclight-emitting display panel comprises a second image driver configuredto apply an image signal to the second organic light-emitting portion.17. The organic light-emitting display of claim 13, wherein the secondorganic light-emitting display panel is substantially verticallyarranged with respect to the first organic light-emitting display panel.18. The organic light-emitting display of claim 13, wherein the imagetransfer unit is further configured to transfer the emitted second imagetoward the light transmissive portion according to one-to-one imagecorrespondence.
 19. The organic light-emitting display of claim 13,wherein the image transfer unit is formed between the first organiclight-emitting display panel and the second organic light-emittingdisplay panel.
 20. The organic light-emitting display of claim 13,wherein the second organic light-emitting display panel is formedbetween the first organic light-emitting display panel and the imagetransfer unit.
 21. An organic light-emitting display comprising: a firstorganic light-emitting display panel comprising: i) a self-emissiveregion and ii) a non-self-emissive region; a second organiclight-emitting display panel spaced apart from the first display paneland configured to emit an image; and an image transfer unit configuredto transfer the emitted image toward the non-light emitting region ofthe first organic light-emitting display panel so that the transferredimage is projected through the non-self-emissive region, wherein theimage transfer unit comprises: a first reflective portion configured tofirst reflect the emitted image; and a second reflective portion formedsubstantially parallel to the first reflective portion, and configuredto reflect the first reflected emitted image toward the lighttransmissive portion, where the first and second reflective portions arerespectively formed on opposing surfaces of a prism.